Sensing & Imaging Components
| Cat | Products Name | Price |
|---|---|---|
| AIMRSE-AIG-SIC-001 | Short-Range 3D LiDAR Sensor Unit | |
| AIMRSE-AIG-SIC-002 | High-Speed eMMC Storage Device | |
| AIMRSE-AIG-SIC-003 | Professional dToF LiDAR Module | |
| AIMRSE-AIG-SIC-004 | Industrial eMCP Storage Unit | |
| AIMRSE-AIG-SIC-005 | Long-Distance LiDAR Scanner | |
| AIMRSE-AIG-SIC-006 | Industrial SPI Flash Storage | |
| AIMRSE-AIG-SIC-007 | Advanced 3D Scanning LiDAR | |
| AIMRSE-AIG-SIC-008 | Secure ePOP Storage Module | |
| AIMRSE-AIG-SIC-009 | High-Precision 3D LiDAR Unit | |
| AIMRSE-AIG-SIC-010 | dToF 3D LiDAR Sensor with Multi-Scan Mode |
Advanced Sensing & Imaging Components for AI Wearables
As the critical "sensory nervous system" of intelligent wearables, our sensing and imaging components capture the high-fidelity environmental data required for advanced AI decision-making. AIMRSE provides a comprehensive suite of miniaturized sensor modules designed to meet the rigorous demands of AI smart glasses, where spatial awareness and human-machine interaction are paramount. Our portfolio includes high-speed global shutter cameras, precision depth sensors, and integrated biometric modules that ensure seamless environmental mapping and intuitive user control. Engineered for sub-microsecond synchronization and extreme energy efficiency, our sensing solutions provide the reliable raw data that powers the next generation of augmented reality and ambient intelligence.
Consult with our integration specialists for sensor fusion calibration, custom lens assemblies, and driver support.
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Product Overview
In the development of AI smart glasses, sensing and imaging components serve as the bridge between the physical world and digital processing. These modules must overcome the challenges of extreme miniaturization—fitting into temple arms and bridge pieces—while delivering the high-speed data flow necessary for SLAM, hand-tracking, and object recognition. Our sensing architecture focuses on reducing "motion-to-photon" latency by ensuring that every frame and data point is captured with perfect temporal accuracy.
- High-Speed Visual Capture: Global shutter technology to eliminate motion blur during rapid head movements.
- Precise Spatial Mapping: Integrated ToF and depth modules for accurate 3D environment reconstruction.
- Human-Centric Biometrics: Advanced eye-tracking and gesture recognition sensors for natural interaction.
- Ultra-Low Power "Always-On": Specialized sensor hubs that monitor the environment with minimal battery drain.
By leveraging advanced packaging technologies like Chip-Scale Packaging (CSP) and integrated flex-circuit designs, AIMRSE components allow hardware designers to maximize interior space for batteries and cooling systems. Our modules are factory-calibrated to ensure consistent performance across large-scale deployments, reducing the complexity of end-of-line testing for OEMs. Whether you are building lightweight consumer frames for daily assistance or heavy-duty industrial visors for complex maintenance tasks, our sensors provide the precision imaging foundation required to make AI truly "perceptive" of its surroundings.
Integrated Sensory Portfolio
Our comprehensive sensory lineup is divided into four functional modules, providing all the essential "senses" required for a fully autonomous AI wearable system. Click below to view performance data for each module:
Global Shutter and High-Resolution CMOS sensors for SLAM and AI vision.
Imaging & Vision Sensors
Our imaging sensors utilize BSI (Back-Side Illuminated) technology for superior low-light sensitivity. Specialized Global Shutter models prevent "jello effects," providing the stable visual data required for high-accuracy tracking.
View Camera Specs
ToF and Structured Light modules for 3D depth perception and hand tracking.
Spatial & Depth Sensing
Compact Time-of-Flight (ToF) modules deliver millimeter-level depth accuracy up to 5 meters. These are essential for room scanning, 3D object manipulation, and ensuring that digital content interacts correctly with physical occlusions.
Check Depth Accuracy
IR sensors and illumination units for gaze tracking and biometric security.
Human-Machine Sensors
Our ultra-miniature IR cameras enable precise eye-tracking for foveated rendering and "glance-based" navigation. Includes integrated 850nm/940nm LED illumination for reliable operation in total darkness.
Compare Sensor FOV
High-SNR MEMS microphones and 6-Axis IMUs for environmental awareness.
Environmental Awareness
Includes high-SNR digital MEMS microphones for voice isolation and 6-axis IMUs for head tracking. Combined with Ambient Light Sensors (ALS), these modules ensure the AI glasses react intelligently to the surrounding environment.
Request Full SpecsKey Features & Technical Advantages
Sub-Microsecond Synchronization
Precise sensor fusion is the backbone of stable AR. Our sensors feature a hardware-level synchronization protocol that aligns visual frames, IMU readings, and depth data with sub-microsecond accuracy. This eliminates tracking drift and ensure that virtual objects appear firmly "locked" to the physical world, even during rapid head movements or complex environmental transitions.
Extreme Low-Light Performance
Equipped with industry-leading pixel sizes and advanced Back-Side Illumination (BSI) sensors, our cameras maintain high Signal-to-Noise Ratios (SNR) in low-light industrial settings. This performance ensures that SLAM and object recognition algorithms remain functional in environments with less than 5 lux of ambient light, making them ideal for night-time operations and dimly lit logistics warehouses.
Ultra-Compact Wearable Design
Every sensor in our portfolio is engineered for extreme miniaturization. By utilizing advanced Wafer-Level Packaging (WLP) and custom-molded optics, we have reduced module volume by up to 40% compared to traditional mobile sensors. This allow for seamless integration into slim temple designs and ultra-lightweight frames, ensuring that AI glasses remain balanced and comfortable for 24/7 continuous wear.
Power-Optimized "Always-On"
Our sensors include proprietary "Smart Wake-up" features that allow for ultra-low power consumption when no motion or relevant visual data is detected. This intelligent power management reduces the sensory system's overall energy footprint, enabling "always-on" voice and gesture monitoring without significantly impacting the battery life of the main control SoC, even during intensive environmental scanning.
Ecosystem & Interface Support
Our sensing modules are designed for plug-and-play compatibility with major Edge AI SoCs, ensuring low-latency data flow across the entire hardware stack.
Technical Parameters Comparison
Detailed specifications for our high-performance sensor modules. All modules are factory-calibrated for rapid deployment.
| Sensor Module | Resolution / Spec | Frame Rate / SNR | Power Consumption | Dimensions (mm) | Shutter Type | Typical Application |
|---|---|---|---|---|---|---|
| V-Imaging Series | 1MP - 8MP | 60 - 120 fps | ~ 150 mW | 4.5 x 4.5 x 3.2 | Global Shutter | SLAM / Vision AI |
| S-Spatial Series | VGA (640x480) | 30 fps (Depth) | ~ 350 mW | 6.0 x 6.0 x 4.5 | iToF / dToF | Hand Track / 3D Mapping |
| B-Biometric IR | 400 x 400 (Custom) | 90 fps | ~ 80 mW | 2.8 x 2.8 x 2.1 | Rolling Shutter | Eye Tracking / ID |
| A-Acoustic Hub | 68dB SNR | N/A (Analog/Digital) | ~ 1.2 mW | 3.5 x 2.5 x 1.0 | N/A | Voice Isolation / ANC |
Need sensor footprints or lens ray-tracing files?
We provide comprehensive SDKs and calibration software to ensure perfect sensor alignment and data fusion.
Typical Application Scenarios
Our sensors enable the precise environmental perception and human interaction required for the next generation of ambient intelligence:
Gesture Control & Interaction
Utilizing our low-latency ToF and hand-tracking cameras, users can interact with digital content using natural hand movements. The system provides 26-point skeletal tracking with millimeter accuracy, enabling complex virtual object manipulation and "air-typing" in professional AR environments.
Gaze-Driven UI & Biometrics
Our miniature eye-tracking sensors enable a "look-to-select" interface, significantly reducing the cognitive load of navigating AR menus. Integrated biometric security also uses these IR sensors for secure login and payment authentication via iris or periocular patterns.
Semantic Scene Understanding
By combining high-resolution visual data with spatial depth mapping, AI glasses can identify specific objects, read text from signs, and provide context-aware information. This semantic understanding allows the device to recognize a kitchen appliance and instantly overlay a repair manual.
Case Studies
Precision SLAM in Harsh Lighting
A leading AR hardware startup struggled with tracking drift in their enterprise headsets when used in environments with direct sunlight and deep shadows. Standard sensors failed to maintain a stable point cloud, leading to virtual content "shifting" during use.
The Solution: Global Shutter + HDR Sensor Fusion
AIMRSE provided a dual-camera global shutter module paired with a high-dynamic-range (HDR) sensor profile. We implemented a hardware-level IMU-vision sync protocol that reduced jitter to under 0.1%. This allowed the headset to maintain a rock-solid tracking anchor even when the wearer moved rapidly between indoor and bright outdoor settings.
Success Highlights
99% Tracking Stability
The implementation achieved a 99% stability rating in variable lighting tests. The client reported a 45% increase in user comfort as the nauseating effect of tracking jitter was eliminated, allowing for professional use shifts of up to 4 hours without visual fatigue.
Why Choose Our Sensing Products
Optical Engineering Expertise
Our team holds deep expertise in lens design and sensor calibration, ensuring that optics and silicon are perfectly matched for high-MTF visual performance in tiny form factors.
Factory-Level Calibration
Every module is individually calibrated for intrinsic and extrinsic parameters in our automated cleanroom facility, providing production-ready data right out of the box.
Comprehensive Driver Support
We provide full-stack drivers for major XR SoCs, along with reference algorithms for SLAM, hand-tracking, and noise cancellation to slash your hardware development time.
Frequently Asked Questions
Why is a Global Shutter sensor preferred over a Rolling Shutter for AI glasses?
Global shutter sensors capture all pixels simultaneously, eliminating the "jello effect" or spatial distortion that occurs with rolling shutters during movement. In AI glasses, head movements are frequent and rapid; global shutter technology ensures that the tracking and SLAM algorithms receive accurate, undistorted frames, which is critical for maintaining stable AR overlays and preventing user motion sickness.
How do you ensure the privacy of visual data captured by these sensors?
Data privacy is handled primarily at the system level, but our sensors support "Private-by-Design" features. We provide specialized hardware-level encryption for data streams and support "local-only" processing, where visual data is processed entirely within the SoC's secure environment and never stored or transmitted to the cloud without explicit user permission.
What is the maximum distance for your depth and ToF sensors?
Our standard ToF (Time-of-Flight) modules are optimized for indoor environments with a ranging distance of 0.2m to 5.0m. For outdoor or industrial requirements, we offer long-range dToF modules capable of detecting surfaces up to 10 meters away with high accuracy, even in bright ambient light conditions exceeding 100k lux.
Can I customize the lens FOV or aperture for a specific sensor module?
Yes. We offer extensive ODM/OEM services for optical assemblies. Depending on your application—whether it's ultra-wide-angle SLAM tracking (120°+ FOV) or high-resolution narrow-angle imaging for text recognition—our optical engineers can design and manufacture custom lens stacks with specific focal lengths, f-numbers, and IR filters to match your requirements.
What is the typical lifespan and reliability of these miniaturized sensors?
Our sensors are engineered for a service life exceeding 30,000 working hours under standard operating conditions. They undergo rigorous reliability testing, including high-temperature aging, humidity cycling, and mechanical drop tests, to ensure they can withstand the typical wear and tear of daily use in both consumer and professional environments.
Related Products
Technical data represent typical values. As applications vary, we recommend consulting our technical team to ensure the best fit for your specific requirements.
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